CN101369075B

CN101369075B - Liquid crystal display device and driving method thereof

Info

Publication number: CN101369075B
Application number: CN200710075773A
Authority: CN
Inventors: 陈弘育
Original assignee: Innolux Shenzhen Co Ltd; Innolux Display Corp
Current assignee: Innolux Shenzhen Co Ltd; Innolux Corp
Priority date: 2007-08-15
Filing date: 2007-08-15
Publication date: 2010-05-26
Anticipated expiration: 2027-08-15
Also published as: CN101369075A; US20090046216A1; US7800705B2

Abstract

The invention relates to an LCD device and a driving method thereof. The LCD device comprises a plurality of scan lines, a plurality of data lines and pixel units which are defined by the scan lines and the data lines. Each pixel unit comprises a first pixel subunit and a second pixel subunit, the first pixel subunit comprises a first film transistor and a first liquid crystal capacitor, the second pixel subunit comprises a second film transistor and a second liquid crystal capacitor, a grid electrode of the first film transistor is connected with the scan lines, a source cathode is connected with the data lines, a drain electrode is connected with the source cathode of the first liquid crystal capacitor and the second film transistor, the grid electrode of the second film transistor is in floating connection, and the drain electrode is connected with the second liquid crystal capacitor. The LCD device has the advantages that the line arrangement is simple, and the cost is low.

Description

Liquid crystal indicator and driving method thereof

Technical field

The present invention relates to a kind of liquid crystal indicator and driving method thereof.

Background technology

Itself does not have the characteristics of luminescence liquid crystal in the liquid crystal indicator, and it is to adopt the electric field controls liquid crystal molecule to reverse and realize passing through or not passing through of light, thereby reaches the purpose of demonstration.The liquid crystal drive mode of tradition liquid crystal indicator is a nematic mode, yet its angular field of view is narrow,, when observing picture from different perspectives, will observe different display effects that is.For solving the narrower problem in nematic mode liquid crystal indicator visual angle, industry proposes a kind of four territory vertical alignment liquid crystal display devices, by a plurality of "＜" shape projection and groove being set at interval on two substrates, each pixel cell is divided into four zones, the orientation difference of the liquid crystal molecule in each zone, enlarge the overall viewing angle of this pixel, and then improve the viewing angle characteristic of liquid crystal indicator.

Yet, because long axis of liquid crystal molecule is different with the optical index of minor axis, will produce color offset phenomenon when observing four territory vertical alignment liquid crystal display devices from different perspectives, influence display quality.For improving the color offset phenomenon of four territory vertical alignment liquid crystal display devices, industry proposes again a pixel cell is divided into two sub-pixel unit, two operating voltages that sub-pixel unit is different are provided, utilize the angle of inclination difference of liquid crystal molecule under the different operating voltage, and a plurality of "＜" shape projection and groove are set make each sub-pixel unit all realize the four territories orientation of liquid crystal molecule on two substrates, thereby eight territories of realizing vertical alignment liquid crystal display device show.

Seeing also Fig. 1 and Fig. 2, is a kind of synoptic diagram of prior art vertical alignment liquid crystal display device, and Fig. 2 is the synoptic diagram of a pixel cell of liquid crystal indicator shown in Figure 1.This liquid crystal indicator 100 comprise that many sweep traces that are parallel to each other 101, many are parallel to each other and with this sweep trace 101 vertically insulated first crossing data lines 103 and second data line 105, a plurality of the first film transistor 111, a plurality of second thin film transistor (TFT) 121, a plurality of first pixel electrode 113, a plurality of second pixel electrode 123, a plurality of public electrode 107, a plurality of first memory capacitance 115 and a plurality of second memory capacitance 125.

This first data line 103 and second data line 105 are provided with successively at interval.This first film transistor 111 is positioned at this sweep trace 101 and these first data line, 103 intersections.The grid of this first film transistor 111 (not indicating) is connected to this sweep trace 101, and source electrode (not indicating) is connected to this first data line 103, and drain electrode (not indicating) is connected to this first pixel electrode 113.This second thin film transistor (TFT) 121 is positioned at this sweep trace 101 and these second data line, 105 intersections.The grid of this second thin film transistor (TFT) 121 (not indicating) is connected to this sweep trace 101, and source electrode (not indicating) is connected to this second data line 105, and drain electrode (not indicating) is connected to this second pixel electrode 123.

This first pixel electrode 113, this public electrode 107 and therebetween liquid crystal molecule (figure does not show) constitute a plurality of first liquid crystal capacitances 117.This first memory capacitance 115 is in parallel with this first liquid crystal capacitance 117.This second pixel electrode 123, this public electrode 107 and therebetween liquid crystal molecule (figure does not show) constitute a plurality of second liquid crystal capacitances 127.This second memory capacitance 125 is in parallel with this second liquid crystal capacitance 127.

One the first film transistor 111, one second thin film transistor (TFT) 121, one first liquid crystal capacitance 117, one second liquid crystal capacitance 127, one first memory capacitance 115 and one second memory capacitance, 125 definition, one pixel cell 130.Wherein, this first film transistor 111, first liquid crystal capacitance 117 and first memory capacitance, 115 definition, one first sub-pixel unit 110; This second thin film transistor (TFT) 121, second liquid crystal capacitance 127 and second memory capacitance, 125 definition, one second sub-pixel unit 120.

This sweep trace 101 is used for controlling the opening and closing of this first film transistor 111 and second thin film transistor (TFT) 121.This first data line 103 be used for when this first film transistor 111 is opened, providing gray scale voltage to this first sub-pixel unit 110 to realize its demonstration; This second data line 105 be used for when this second thin film transistor (TFT) 121 is opened, providing gray scale voltage to this second sub-pixel unit 120 to realize its demonstration.Because this first sub-pixel unit 110 and second sub-pixel unit 120 provide gray scale voltage by these two data lines 103,105 respectively, thereby make these two sub-pixel unit 111,121 have different operating voltages, further cooperate "＜" shape projection and groove, this liquid crystal indicator 100 can realize that eight territories show.

Yet a pixel cell 130 of this liquid crystal indicator 100 needs two data lines 103,105 to drive, and makes that these liquid crystal indicator 100 wirings are complicated, cost is higher.

Summary of the invention

For solving complicated, the cost problem of higher of liquid crystal indicator wiring in the prior art, be necessary to provide a kind of wiring simple, lower-cost liquid crystal indicator.

In addition, also be necessary to provide a kind of driving method of above-mentioned liquid crystal indicator.

A kind of liquid crystal indicator, it comprises the multi-strip scanning line, many the data lines that intersect with the insulation of this sweep trace and a plurality of this sweep trace and data line intersect the pixel cell that the Minimum Area that surrounds defines, each pixel cell comprises one first sub-pixel unit and one second sub-pixel unit, this first sub-pixel unit comprises a first film transistor and one first liquid crystal capacitance, this second sub-pixel unit comprises one second thin film transistor (TFT) and one second liquid crystal capacitance, the transistorized grid of this first film is connected to this sweep trace, source electrode is connected to this data line, drain electrode is connected to the source electrode of this first liquid crystal capacitance and this second thin film transistor (TFT), the grid suspension joint of this second thin film transistor (TFT), drain electrode is connected to this second liquid crystal capacitance.

A kind of liquid crystal indicator, it comprises the multi-strip scanning line, many the data lines that intersect with the insulation of this sweep trace and a plurality of this sweep trace and data line intersect the pixel cell that the Minimum Area that surrounds defines, each pixel cell comprises one first sub-pixel unit and one second sub-pixel unit, this first sub-pixel unit comprises a first film transistor and one first liquid crystal capacitance, this second sub-pixel unit comprises one second thin film transistor (TFT), one the 3rd thin film transistor (TFT) and one second liquid crystal capacitance, the transistorized grid of this first film is connected to this sweep trace, source electrode is connected to this data line, drain electrode is connected to this first liquid crystal capacitance, the grid of the 3rd thin film transistor (TFT) is connected to this sweep trace, source electrode is connected to this data line, drain electrode is connected to the source electrode of this second thin film transistor (TFT), the grid suspension joint of this second thin film transistor (TFT), drain electrode is connected to this second liquid crystal capacitance.

A kind of driving method of liquid crystal indicator, this liquid crystal indicator comprises the multi-strip scanning line, many the data lines that intersect with the insulation of this sweep trace and a plurality of sweep trace and data line intersect a plurality of pixel cells that the Minimum Area that surrounds defines, each pixel cell comprises one first sub-pixel unit and one second sub-pixel unit, this first sub-pixel unit comprises a first film transistor and one first liquid crystal capacitance, this second sub-pixel unit comprises one second thin film transistor (TFT) and second liquid crystal capacitance, the transistorized grid of this first film is connected to this sweep trace, the grid suspension joint of this second thin film transistor (TFT), this driving method comprises the steps:

A. provide the inferior sweep signal of i (i is a natural number) to this n (n is a natural number) horizontal scanning line, gray scale voltage on the same data line is given this first liquid crystal capacitance charging via the transistorized source electrode of this first film, drain electrode, also gives this second liquid crystal capacitance charging via source electrode, the drain electrode of this second thin film transistor (TFT); With

B. stop to provide sweep signal to arrive this n horizontal scanning line, this first film transistor is closed.

With respect to prior art, in liquid crystal indicator of the present invention and the driving method thereof, when the gray scale voltage on the same data line is given this first liquid crystal capacitance and the charging of this second liquid crystal capacitance, grid suspension joint because of this second thin film transistor (TFT), there is a constant impedance between its source electrode and the drain electrode, thereby the charging current of this second liquid crystal capacitance is less than the charging current of this first liquid crystal capacitance, make this first liquid crystal capacitance have different voltage and realize that eight territories show with second liquid crystal capacitance, because these two sub-pixel unit only need a data line to drive, and then this liquid crystal indicator wiring is simple, cost is lower.

Description of drawings

Fig. 1 is a kind of synoptic diagram of prior art vertical alignment liquid crystal display device.

Fig. 2 is the synoptic diagram of a pixel cell of liquid crystal indicator shown in Figure 1.

Fig. 3 is the synoptic diagram of first embodiment of liquid crystal indicator of the present invention.

Fig. 4 is the synoptic diagram of a pixel cell of liquid crystal indicator shown in Figure 3.

Fig. 5 is the synoptic diagram of a pixel cell of second embodiment of liquid crystal indicator of the present invention.

Embodiment

See also Fig. 3 and Fig. 4, Fig. 3 is the synoptic diagram of liquid crystal indicator first embodiment of the present invention, and Fig. 4 is the synoptic diagram of a pixel cell of liquid crystal indicator shown in Figure 3.This liquid crystal indicator 200 comprises that many sweep traces that are parallel to each other 201, many are parallel to each other and intersects the pixel cell 230 of minimum rectangular area definition that surrounds with the vertically insulated crossing data lines 203 of this sweep trace 201 and a plurality of these sweep traces 201 and this data line 203.

Each pixel cell 230 comprises one first sub-pixel unit 210 and one second sub-pixel unit 220.This first sub-pixel unit 210 comprises a first film transistor 211, one first pixel electrode 213, a public electrode 207 and one first memory capacitance 215.This second sub-pixel unit comprises one second thin film transistor (TFT) 221, one second pixel electrode 223, a public electrode 207 and one second memory capacitance 225.

The grid of this first film transistor 211 (not indicating) is connected to this sweep trace 201, and source electrode (not indicating) is connected to this data line 203, and drain electrode (not indicating) is connected to the source electrode (not indicating) of this first pixel electrode 213 and this second thin film transistor (TFT) 221.The grid of this second thin film transistor (TFT) 221 (not indicating) suspension joint (floating), drain electrode (not indicating) is connected to this second pixel electrode 223.

This public electrode 207 and this first pixel electrode 213 and therebetween a plurality of first liquid crystal capacitances 217 of liquid crystal molecule (figure does not show) formation are also with this second pixel electrode 223 and therebetween a plurality of second liquid crystal capacitances 227 of liquid crystal molecule (figure does not show) formation.This first liquid crystal capacitance 217 is in parallel with this first memory capacitance 215, and this second liquid crystal capacitance 227 is in parallel with this second memory capacitance 225.

The principle of work of this liquid crystal indicator 200 is as follows:

A plurality of sweep signals are provided to each horizontal scanning line 201 successively, when n (n is a natural number) horizontal scanning line 201 i (i is a natural number) are inferior be provided sweep signal during, the first film transistor 211 on this row is opened, simultaneously, gray scale voltage on this data line 203 makes this first

liquid crystal capacitance

217 and 215 chargings of first memory capacitance via the source electrode of this first film transistor 211, this first pixel electrode 213 that drains; This gray scale voltage is also via the source electrode of this first film transistor 211, the source electrode of second thin film transistor (TFT) 221 that drains.

Because these second thin film transistor (TFT), 221 suspension joints, there is impedance between its source electrode and the drain electrode, thereby this gray scale voltage is given this second liquid crystal capacitance 227 and the charging of second memory capacitance via this impedance, its charging current is littler than the charging current of this first liquid crystal capacitance 217 and second memory capacitance, make this second liquid crystal capacitance, 227 charge ratios, first liquid crystal capacitance 217 slow, control this first and second thin film transistor (TFT) 211,221 ON time, make this second liquid crystal capacitance 227 have different voltage with first liquid crystal capacitance 217, this first memory capacitance 215 also has different voltage with second memory capacitance 225.

The i time sweep signal of this n horizontal scanning line 201 is closed to before the i+1 time sweep signal be provided, this first memory capacitance 215 keeps the voltage of this first liquid crystal capacitance 217, this second memory capacitance 225 keeps the voltage of this second liquid crystal capacitance 227, to keep the demonstration of this first sub-pixel unit 210 and second sub-pixel unit 220.

With respect to prior art, in the liquid crystal indicator 200 of the present invention, when the gray scale voltage on the same data line 203 is given this first

liquid crystal capacitance

217 and 227 chargings of this second liquid crystal capacitance, grid suspension joint because of this second thin film transistor (TFT) 221, there is a constant impedance between its source electrode and the drain electrode, thereby the charging current difference of these two liquid crystal capacitances 217,227, and then this first liquid crystal capacitance 217 has different voltage with second liquid crystal capacitance 227.Because data line of 210,220 needs of these two sub-pixel unit 203 drives, can realize that eight territories show, and then these liquid crystal indicator 200 wirings are simple, cost is lower.

In addition, because the impedance between the source of this second thin film transistor (TFT) 221, the drain electrode is influenced by the current potential of its grid, and exist overlapping region to produce a stray capacitance between its grid and the source electrode, when the source potential of this second thin film transistor (TFT) 221 changes, the current potential of this grid is subjected to affecting of source potential and changes, so its source, the drain electrode between impedance change.

In general, the source potential of this second thin film transistor (TFT) 221 is high more, and the current potential that this grid is inducted is high more, and the impedance between its source, the drain electrode is more little; Otherwise the source potential of this second thin film transistor (TFT) 221 is low more, and the current potential that this grid is inducted is low more, and the impedance between its source, the drain electrode is big more.

Therefore, when this pixel cell 230 shows white picture (for the common-black type liquid crystal indicator), the gray scale voltage that this data line 203 provides is higher, thereby the impedance between the source electrode of this second thin film transistor (TFT) 221 and the drain electrode is less, this gray scale voltage gives the charging current of these second liquid crystal capacitance, 227 chargings bigger, charging current near this first liquid crystal capacitance 217, thereby, this first liquid crystal capacitance 217 is basic identical with these second liquid crystal capacitance, 227 voltages, this first sub-pixel unit 210 is basic identical with these second sub-pixel unit, 220 brightness, thereby the white picture of this liquid crystal indicator 200 is near bright entirely.

When picture is deceived in these pixel cell 230 demonstrations, the gray scale voltage that this data line 203 provides is less, thereby the impedance between the source electrode of this second thin film transistor (TFT) 221 and the drain electrode is bigger, this second thin film transistor (TFT) 221 is no current almost, thereby this second sub-pixel unit 220 presents the black picture darker than first sub-pixel unit 210, and the black picture of this liquid crystal indicator 200 is darker.To sum up, this liquid crystal indicator 200 still can keep contrast preferably when realizing that eight territories show.

Seeing also Fig. 5, is the synoptic diagram of a pixel cell of liquid crystal indicator second embodiment of the present invention.The difference of the liquid crystal indicator of this liquid crystal indicator and first embodiment only is: second sub-pixel unit 320 further comprises one the 3rd thin film transistor (TFT) 329, whether it writes the on-off element of second sub-pixel unit 320 as the control gray scale voltage, wherein, the grid of the 3rd thin film transistor (TFT) 329 (not indicating) is connected to sweep trace 301, source electrode (not indicating) is connected to data line 303, and drain electrode (not indicating) is connected to the source electrode (not indicating) of second thin film transistor (TFT) 321.

It is described that liquid crystal indicator of the present invention is not limited to above-mentioned embodiment, as: in second embodiment, the source electrode of the 3rd thin film transistor (TFT) 329 can be free of attachment to this data line 303, and being connected to the first film transistor drain, the gray scale voltage on this data line 303 writes this second sub-pixel unit 320 via source electrode, the drain electrode of the transistorized source electrode of this first film, drain electrode and the 3rd thin film transistor (TFT) 329.

Claims

1. liquid crystal indicator, it comprises the multi-strip scanning line, many the data lines that intersect with the insulation of this sweep trace and a plurality of this sweep trace and data line intersect the pixel cell that the Minimum Area that surrounds defines, each pixel cell comprises one first sub-pixel unit and one second sub-pixel unit, this first sub-pixel unit comprises a first film transistor and one first liquid crystal capacitance, this second sub-pixel unit comprises one second thin film transistor (TFT) and one second liquid crystal capacitance, the transistorized grid of this first film is connected to this sweep trace, source electrode is connected to this data line, drain electrode is connected to this first liquid crystal capacitance, the drain electrode of this second thin film transistor (TFT) connects this second liquid crystal capacitance, it is characterized in that: the grid suspension joint of this second thin film transistor (TFT), source electrode connect this first film transistor drain.

2. liquid crystal indicator as claimed in claim 1, it is characterized in that: this second sub-pixel unit further comprises one the 3rd thin film transistor (TFT), its grid is connected to this sweep trace, and this first film transistor drain is the source electrode via the 3rd thin film transistor (TFT), the source electrode that drain electrode is connected to this second thin film transistor (TFT).

3. liquid crystal indicator as claimed in claim 1, it is characterized in that: this first liquid crystal capacitance comprises one first pixel electrode, a public electrode and therebetween liquid crystal molecule, this the first film transistor drain is connected to this first pixel electrode, this second liquid crystal capacitance comprises one second pixel electrode, a public electrode and therebetween liquid crystal molecule, and the drain electrode of this second thin film transistor (TFT) is connected to this second pixel electrode.

4. liquid crystal indicator as claimed in claim 1, it is characterized in that: this first sub-pixel unit further comprises one first memory capacitance, it is in parallel with this first liquid crystal capacitance, and this second sub-pixel unit further comprises one second memory capacitance, and it is in parallel with this second liquid crystal capacitance.

5. liquid crystal indicator, it comprises the multi-strip scanning line, many the data lines that intersect with the insulation of this sweep trace and a plurality of this sweep trace and data line intersect the pixel cell that the Minimum Area that surrounds defines, each pixel cell comprises one first sub-pixel unit and one second sub-pixel unit, this first sub-pixel unit comprises a first film transistor and one first liquid crystal capacitance, this second sub-pixel unit comprises one second thin film transistor (TFT) and one second liquid crystal capacitance, the transistorized grid of this first film is connected to this sweep trace, source electrode is connected to this data line, drain electrode is connected to this first liquid crystal capacitance, the drain electrode of this second thin film transistor (TFT) connects this second liquid crystal capacitance, it is characterized in that: this second sub-pixel unit also comprises one the 3rd thin film transistor (TFT), the grid of the 3rd thin film transistor (TFT) is connected to this sweep trace, source electrode is connected to this data line, drain electrode is connected to the source electrode of this second thin film transistor (TFT), the grid suspension joint of this second thin film transistor (TFT).

6. the driving method of a liquid crystal indicator, this liquid crystal indicator comprises the multi-strip scanning line, many the data lines that intersect with the insulation of this sweep trace and a plurality of sweep trace and data line intersect a plurality of pixel cells that the Minimum Area that surrounds defines, each pixel cell comprises one first sub-pixel unit and one second sub-pixel unit, this first sub-pixel unit comprises a first film transistor and one first liquid crystal capacitance, this second sub-pixel unit comprises one second thin film transistor (TFT) and second liquid crystal capacitance, the transistorized grid of this first film is connected to this sweep trace, the grid suspension joint of this second thin film transistor (TFT), this driving method comprises the steps:

7. the driving method of liquid crystal indicator as claimed in claim 6, it is characterized in that: among the step a, the gray scale voltage on the same data line is to give this second liquid crystal capacitance charging via the source electrode of the transistorized source electrode of this first film, drain electrode and this second thin film transistor (TFT), drain electrode.

8. the driving method of liquid crystal indicator as claimed in claim 6, it is characterized in that: this second sub-pixel unit further comprises one the 3rd thin film transistor (TFT), the 3rd film crystal tube grid is connected to this sweep trace, source electrode is connected to this data line, drain electrode is connected to the source electrode of this second thin film transistor (TFT), among the step a, the gray scale voltage on the same data line is to give this second liquid crystal capacitance charging via the source electrode of the source electrode of the 3rd thin film transistor (TFT), drain electrode and this second thin film transistor (TFT), drain electrode.

9. the driving method of liquid crystal indicator as claimed in claim 6, it is characterized in that: this first sub-pixel unit further comprises one first memory capacitance, this first liquid crystal capacitance is in parallel with this first memory capacitance, among the step a, gray scale voltage on the same data line is given this first memory capacitance charging via the transistorized source electrode of this first film, drain electrode, among the step b, this first memory capacitance keeps the voltage of this first liquid crystal capacitance.

10. the driving method of liquid crystal indicator as claimed in claim 6, it is characterized in that: this second sub-pixel unit comprises one second memory capacitance, this second liquid crystal capacitance is in parallel with this second memory capacitance, among the step a, gray scale voltage on the same data line is given this second memory capacitance charging via source electrode, the drain electrode of the transistorized source electrode of this first film, drain electrode and this second thin film transistor (TFT), among the step b, this second memory capacitance keeps the voltage of this second liquid crystal capacitance.